Mathematics, 19.04.2020 04:06, jesuscruzm2020
The average number of accidents at controlled intersections per year is 5.3. Is this average more for intersections with cameras installed? The 51 randomly observed intersections with cameras installed had an average of 5.9 accidents per year and the standard deviation was 1.93. What can be concluded at the
α = 0.01 level of significance?
For this study, we should use
The null and alternative hypotheses would be:
H
0
:
H
1
:
The test statistic =
(please show your answer to 3 decimal places.)
The p-value =
(Please show your answer to 4 decimal places.)
The p-value is
α
Based on this, we should the null hypothesis.
Thus, the final conclusion is that ...
The data suggest that the sample mean is not significantly more than 5.3 at
α
= 0.01, so there is statistically insignificant evidence to conclude that the sample mean number of accidents per year at intersections with cameras installed is more than 5.9 accidents.
The data suggest that the populaton mean is significantly more than 5.3 at
α
= 0.01, so there is statistically significant evidence to conclude that the population mean number of accidents per year at intersections with cameras installed is more than 5.3 accidents.
The data suggest that the population mean is not significantly more than 5.3 at
α
= 0.01, so there is statistically insignificant evidence to conclude that the population mean number of accidents per year at intersections with cameras installed is more than 5.3 accidents.
Interpret the p-value in the context of the study.
If the population mean number of accidents per year at intersections with cameras installed is 5.3 and if another 51 intersections with cameras installed are observed then there would be a 1.54860321% chance that the sample mean for these 51 intersections with cameras installed would be greater than 5.9.
If the population mean number of accidents per year at intersections with cameras installed is 5.3 and if another 51 intersections with cameras installed are observed then there would be a 1.54860321% chance that the population mean number of accidents per year at intersections with cameras installed would be greater than 5.3.
There is a 1.54860321% chance that the population mean number of accidents per year at intersections with cameras installed is greater than 5.3 .
There is a 1.54860321% chance of a Type I error.
Interpret the level of significance in the context of the study.
There is a 1% chance that you will get in a car accident, so please wear a seat belt.
If the population mean number of accidents per year at intersections with cameras installed is 5.3 and if another 51 intersections with cameras installed are observed then there would be a 1% chance that we would end up falsely concuding that the population mean number of accidents per year at intersections with cameras installed is more than 5.3.
There is a 1% chance that the population mean number of accidents per year at intersections with cameras installed is more than 5.3.
If the population population mean number of accidents per year at intersections with cameras installed is more than 5.3 and if another 51 intersections with cameras installed are observed then there would be a 1% chance that we would end up falsely concuding that the population mean number of accidents per year at intersections with cameras installed is equal to 5.3.
Answers: 3
Mathematics, 21.06.2019 16:40, lawrencebenoit7194
This question awards 100 ! i really don’t want to fail i will also mark you !
Answers: 2
Mathematics, 21.06.2019 19:30, danielahchf
Ineed with angles and the measure of them i have abc a is 65 and b is (3x-10) and c is (2x) find the value of x
Answers: 2
Mathematics, 21.06.2019 20:00, serianmollel
Which statement about the annual percentage rate (apr) is not true?
Answers: 3
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